1250 Millen, Hawkes
Macromolecules
111-CHC13 show clearly the presence and effect of hydrogen bonding of I to the polymer. T o a good approximation probe I behaves as if it were covalently bonded to PMMA. In DMF probe I was expected to hydrogen bond to the solvent with increasing solvent concentration. The extreme similarity between these data and PMMA-I' makes any detailed interpretation impossible. Acknowledgments. This work was supported in part by the US. Public Health Service (GM-16922), by the Education Committee of the Rubber Division, American Chemical Society, and by the donors of the Petroleum Research Fund, administered by the American Chemical Society. References a n d Notes (1) On leave of absence from Institute Ruaer BoSkoviC, Zagreb, Yugoslavia. (2) (a) Z. Veksli and W. G. Miller, Macromolecules, 10,686 (1977); (b) J. Fujita and A. Kishimoto, J. Chem. Phys., 34,393 (1961). (3) A. L. Buchachenko, A. L. Kovarskii, and A. M. Wasserman, Adu. Polym. Sci., 26 (1976).
(4) P. Tormala and J. J. Lindberg, "Structural Studies of Macromolecules
by Spectroscopic Methods", K. J. Ivin, Ed., Wiley, New York, N.Y., 1976, pp 255-272. (5) P. L. Kumler and R. F. Boyer, Macromolecul s, 9,903 (1976). (6) E. L. Wee and W. G. Miller, J . Phys. Chem., $7,182 (1973). (7) C. C. Wu and W. G. Miller, Macromolecules, in press. ( 8 ) R. P. Mason, C. F. Polnaszek, and J. H. Freed, J . Phys. Chem., 78,1324 (1974). (9) A. L. Kovarskii, Thesis, IKhF AN SSR, Moscow, 1972. (10) R. P. Mason and J. H. Freed, J . Phys. Chem., 78,132 (1974). (11) R. P. Mason, E. B. Giavedoni, and A. P. Delmasso, Biochemistry, in press. (12) A. T . Bullock, G. G. Cameron, and P. M. Smith, Eur. Polym. J . , 11,617 (1975). (13) D. Kivelson, J . Chem. Phys., 33,1094 (1960). (14) K. J. Liu and R. J. Ullman, J . Chem. Phys., 48,1158 (1968). (15) J. F. Anderson and K. J. Liu, J . Chem. Phys., 49,2850 (1968). (16) W. G. Rothschild, Macromolecules, 5,37 (1972). (17) F. Heatley and J. H. Scrivens, Polymer, 16,489 (1975). (18) W. G. Rothschild, Macromolecules, 1 , 4 3 (1968). (19) G. P. Rabold, J . Polym. Sci., Part A-1, 7,1203 (1969). (20) N. Kusumoto, M. Yonezawa, and Y. Motozato, Polymer, 15, 793 (1974). (21) A. T. Bullock, G. G. Cameron, and P. M. Smith, Eur. Polym. J., 11,617 (1975).
Diffusion of n -Alkanes in Poly(dimethylsiloxanes) William Millen a n d Stephen Hawkes* Department of Chemistry, Oregon State University, Corvallis, Oregon 97331 Received February 4 , 1977 ABSTRACT: Plots of n-alkane carbon number against diffusional friction coefficient in two dimethylsiloxanes of different molecular weight (4 X lo5 and 3.5 X lo4)intersect. It is proposed that diffusion of shorter n-alkanes is governed by free volume which is greater in the higher molecular weight polymer, while diffusion of the longer n-alkanes is governed by segmental relaxation speed which is greater in the lower polymer. The specific volume of the higher ~ m ~ / c m over ~ / ~the C range 30 to 250 "C. polymer at 100 "C is 1.102 and the coefficient of expansion is 9.98 X The nonlinearity of the friction coefficient with n-alkane carbon number is confirmed. Unusually high diffusion coefficients for n-alkanes in the highly viscous poly(dimethylsi1oxane) gum (General Electric "SE-30") (9.5 X lo6 cSt at 25 "C, mol wt = 4 X lo5) relative to less viscous poly(dimethylsi1oxanes) have been noted by Butler and Hawkesl and Kong and H a ~ k e s . ~Their ,3 work with SE-30 and General Electric "SF-96-2000" (2000 cSt at 25 "C, mol wt = 3.5 X lo4) has been repeated using a more rigorous equation4 for determining diffusion coefficients from chromatographic data. In addition, their work has been extended to include diffusivities of some higher molecular weight n-alkanes which they had been unable to determine. Calculation of Friction Coefficients The friction coefficient for a molecule at vanishingly small concentrations in the bulk of a polymer can be calculated using the equation (1
kT/D
where k is the Boltzmann constant and D is the diffusivity of the penetrant. The diffusivities of a series of n-alkanes in SE-30 and SF-96-2000 a t various temperatures have been determined,4and the friction coefficients calculated from eq 1 are listed in Table I. Auerbach et al.5 have suggested that the friction coefficient for n-alkanes in polymers is approximately linear with the chain length of the n-alkane. This was not found to be the case for n-alkanes in a variety of polysiloxanes3 and is also inconsistent with the data in Table I which are plotted in Figures 1 and 2 and are clearly nonlinear.
The friction coefficient for a monomer unit of a polymer, has been shown by Ferry6 to be approximately equal to {I for a penetrating molecule of the same size. This proposal can be shown to be consistent with data calculated here by extrapolating the log (1 values at 100 "C for the lowest two n alkanes in Table I linearly down to n-pentane. The results of this extrapolation are shown in Table I1 along with the (0 value listed by Ferry6 for a monomer unit for a poly(dimethy1siloxane). (0,
Density a n d Expansion Coefficient of SE-30 The unusually high diffusivity of a few n-alkanes in SE-30 has been noted p r e v i ~ u s l y l and - ~ it has been suggested3 that these high diffusivities (low fl) are due to the higher free volume present in SE-30 which is evidenced by its lower density relative to the lower molecular weight poly(dimethylsiloxanes). While a literature value was available,l the unusual diffusion characteristics of n-alkanes in SE-30 seemed to warrant an independent determination of its density and thermal expansion coefficient. Accordingly, the density of SE-30 was measured between 30 and 250 "C using a stainless steel density bottle and the results are listed in Table 111. The thermal expansion coefficient was determined by a linear regression analysis of the specific volume listed in Table 111,against temperature, and resulted in the following equation for specific volume v in cm3/g where T is in "C, 1.002 is is therefore the the specific volume a t 0 "C, and 9.98 X thermal expansion coefficient.
Diffusion of n-Alkanes in Poly(dimethylsi1oxanes) 1251
Vol. 10, No. 6, November-December 1977
Table I Friction Coefficients for n-alkanes in SE-30 and SF-96-2000 X
109, dyn s/cm
SE-30 50 "C n-Heptane n-Octane n-Nonane n-Decane n-Undecane n-Dodecane n-Tridecane n-Tetradecane n -Hexadecane n-Octadecane rz-Docosane n-Tetracosane n-Octacosane
150 "C
100 "C
6.09 7.52 10.1 14.3 23.6 46.4 92.4
SF-96-2000
4.12 4.48 5.47 6.47 9.49 15.7 25.4 67.2 256
50 "C
200 "C
100 "C
8.07 9.45 11.3 14.3 19.4 30.8 53.5
3.26 3.95 4.79 6.12 10.0 23.4 129
4.95 5.75 6.41 7.42 9.04 11.1
3.25 3.91 5.43 15.3 26.2 148
14.5 36.8 114
I20
250 110 100 90
200
0 a
; 80 ul W
70
T=5Oo
n
8
3
loo/
60
\ 0 W
50
z W
X
u;
150
>
0 40
0,
0
150"
200/
X
30
-
xfl
100
20 IO
8
IO
12
14
I6
18
50
CARBON NUMBER
Figure 1. Translational friction coefficients for n-alkanes in SE-30 = 1.002
+ 9.98 x 10-427
(2)
The correlation coefficient, R , for the regression was 0.998 and the standard error for the expansion coefficient was 1.6 X 10-5 cm3/cm3/"C. The density and expansion coefficient for SE-30 are compared with the literature values7 of some other poly(dimethylsiloxanes) in Table IV. One can see that the density of SE-30 is less than all of the poly(dimethylsi1oxanes) listed, which implies a higher free volume for SE-30.
Effect of Free Volume and Viscosity on Friction Coefficients By determining friction coefficients for a greater number of n-alkanes than Kong and Hawkes did for SE-30 and SF96-2000 and by plotting {I against carbon number on the same graph, Figure 3, one observes that the data for the two polymers cross each other. As both polymers have identical chemical structures (end group differences being negligable) energy terms will be identical or nearly so in both polymers
8
IO
12
14
16
I8
20
22
24
26
28
CARBON NUMBER
Figure 2. Translational friction coefficients for n-alkanes in SF96 - 2000
and the differences in friction coefficient must be the result of differences in the physical properties of the polymers. The difference is easily explained for the lower n-alkanes as a result of the higher free volume of the higher polymer. As the size of the alkane increases, however, pockets of free volume become less accessible and diffusion must be assisted increasingly by thermal motions of the polymer chain. These may either be the natural motions of the polymer or may be induced by the motion of the alkane. Such motions are typical of high-frequency viscosity measurements6 and it is knownE that high-frequency viscosity is greater in the higher polymers although not so much higher as the regular viscosity obtained from flow measurements.
1252 Millen, Hawkes
Macromolecules
Table I1 Comparison of Friction Coefficients at 100 "C n-pentane In SE-30 In SF-96-2000 Siloxane monomer unit
/
f, dyn s/cm
Mol wt
l00.p
400[ 200
72 3.0 x 10-9 2.6 x 10-9 2.82 x 10-9
74
Table I11 Specific Volume of SE-30 T*I"C
u,
cm3/g
T*l0C
1.0323 1.0520 1.0715 1.0887 1.1152 1.1316 1.1334
30
50 70 90 110 130 133
u,
151 154 171 190 210 231 250
cm3/g
1.1492 1.1555 1.1653 1.2006 1.2085 1.2137 1.2523
2t
Table IV ProDerties of Polv(dimethvlsi1oxanes) Viscasil SE-30 Viscosity ctks at 25 "C Av mol wt MW Sp gr at 25/25 "C Coefficient of expansion a
100 000
9.47 x 106 100000
SF-962000 2000
9.25 X 10-4
9.25 X 10-4
I
8
1
IO
200
4.0 X lo5 1.03 X lo5 3.50 X lo4 1.1 X lo4 0.971" 0.978 0.974 0.972 9.98 X
I
SF-96-200
9.25 X 10-4
Calculated from eq 2 correcting for density of water at 25
"C. We propose therefore that the higher n-alkanes diffuse more freely in the lower polymer because of faster thermal motions of the polymer chain and that lower n-alkanes diffuse more freely in the higher polymer because of its greater free volume. I t is possible that there is some contribution from self-diffusion of the polymer but as this is of the order of cm2/s in the lower polymer and 10-lo in the higherg the effect on alkane diffusion coefficients near is likely to be small. The differences in the expansion coefficients noted in Table IV could be instrumental in proving these assertions in that, below 12 "C, SE-30 would be denser than the SF-96-200 (-17 "C for SF-96-2000) and diffusion of n-alkanes of any molecular weight should be slower in the SE-30. This will be the subject of a future experimental project. The data on which Auerbach et al. based the assertion that { is linear with carbon number was mostly from penetrants with carbon numbers 1to 5, which is lower than the shortest penetrants used here and their diffusion would, if the above explanation is correct, be controlled solely by the free volume effect and not a t all by the relaxation time. This suggests that
12
I
I
,
14
16
18
CARBON NUMBER
Figure 3. Translational friction coefficients for n-alkanes in two poly(dimethylsi1oxanes): ( 0 )SE-30; ( 8 )SF-96-2000at 50 and 100 "C.
the linear relation would hold as a limiting case for short-chain penetrants. More extensive data on better characterized polymers would provide a sensitive test of quantitative theories of diffusion: free volume can be varied by varying the molecular weight of the polymer without changing the chemical characteristics of the system or the temperature, and without using polymers below the critical molecular weight for entanglement or with substantial polymer-end or Flory-Huggins statistical effects. Acknowledgment. This work was supported by NSF Grant GP-15430. References and Notes (1) L. Butler and S. J.Hawkes, J . Chromatogr. Sci., 10,518 (1972). (2) J. M. Kong and S. J. Hawkes, J . Chrornatogr. Sci., 14,279 (1976). (3) J. M.Kong and S. J. Hawkes, Macromolecules, 8,685 (1975). ( 4 ) W. G. Millen and S. J. Hawkes, J . Chromatogr. Sci., 15,148 ( 1 9 i i ) .
( 5 ) I. Auerbach, S. D. Gehman, W. R. Miller, and W. C. Kuryla, J . I'oljrn. Sci., 28,129 (1958). (6) J. D. Ferry, "Viscoelastic Properties of Polymers", Wiley, New York, N.Y., 1970, Chapter 12. ( 7 ) Technical Data Book, S 9 B , General Electric Co., Silicone Products Department, Waterford, N.Y., (8) J. Lamb and P. Lindon, J . Acoust. Soc. A m . , 41, 1032 (1967). (9) J. E. Tanner, K-J. Liu, and J. E. Anderson, Mmrornolecules, 4, 586 (1971).